/*=========================================================================
 *
 *  Copyright Insight Software Consortium
 *
 *  Licensed under the Apache License, Version 2.0 (the "License");
 *  you may not use this file except in compliance with the License.
 *  You may obtain a copy of the License at
 *
 *         http://www.apache.org/licenses/LICENSE-2.0.txt
 *
 *  Unless required by applicable law or agreed to in writing, software
 *  distributed under the License is distributed on an "AS IS" BASIS,
 *  WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 *  See the License for the specific language governing permissions and
 *  limitations under the License.
 *
 *=========================================================================*/
// Disable warning for long symbol names in this file only

#include <itkRecursiveGaussianImageFilter.h>
#include <itkImageRegionIterator.h>

namespace
{

bool
NormalizeSineWave(double frequencyPerImage, unsigned int order, double pixelSpacing = 1.0)
{
  // for an image f(x) = sin ( w*x ), where w is a measure of
  // frequency, this methods verifies that the normalized scale-scale
  // is with in reasonable tolerance of the theoretical value.

  constexpr unsigned int ImageDimension = 1;
  constexpr unsigned int imageSize = 1024;
  const double           tol = std::pow(.000001, 1.0 / order);

  double frequency = frequencyPerImage * 2.0 * itk::Math::pi / (imageSize * pixelSpacing);

  // The theoretical maximal value should occur at this sigma
  double sigma_max = std::sqrt(double(order)) / frequency;

  // the theoreical maximal value of the derivative, obtained at sigma_max
  double expected_max = std::pow(double(order), order * 0.5) * std::exp(-0.5 * order);

  using ImageType = itk::Image<double, ImageDimension>;
  ImageType::Pointer image = ImageType::New();

  ImageType::SizeType size;
  size.Fill(imageSize);

  image->SetRegions(ImageType::RegionType(size));
  image->Allocate();

  ImageType::SpacingType spacing;
  spacing.Fill(pixelSpacing);

  image->SetSpacing(spacing);

  itk::ImageRegionIterator<ImageType> iter(image, image->GetBufferedRegion());

  // create sine wave image
  while (!iter.IsAtEnd())
  {
    ImageType::PointType p;
    image->TransformIndexToPhysicalPoint(iter.GetIndex(), p);
    const double x = p[0];
    double       value = std::sin(x * frequency);

    iter.Set(value);
    ++iter;
  }


  using GaussianFilterType = itk::RecursiveGaussianImageFilter<ImageType, ImageType>;
  GaussianFilterType::Pointer filter = GaussianFilterType::New();
  filter->SetInput(image);
  filter->SetDirection(0);
  filter->SetSigma(sigma_max);
  switch (order)
  {
    case 1:
      filter->SetOrder(itk::GaussianOrderEnum::FirstOrder);
      break;
    case 2:
      filter->SetOrder(itk::GaussianOrderEnum::SecondOrder);
      break;
    default:
      std::cerr << " only support order 1 and 2" << std::endl;
      return false;
  }
  filter->SetNormalizeAcrossScale(true);

  // The derivative need to be scaled
  //
  // All .Get() methods should be multiplied by this
  const double scaleFactor = std::pow(1.0 / pixelSpacing, double(order));

  ImageType::Pointer outputImage = filter->GetOutput();
  outputImage->Update();

  // maximal value of the first derivative
  double maxLx = itk::NumericTraits<double>::NonpositiveMin();

  itk::ImageRegionConstIterator<ImageType> oiter(outputImage, outputImage->GetBufferedRegion());

  while (!oiter.IsAtEnd())
  {
    maxLx = std::max(maxLx, oiter.Get() * scaleFactor);
    ++oiter;
  }

  // check if the maximal is obtained with a little bit smaller Gaussian
  filter->SetSigma(sigma_max * 0.95);
  outputImage->Update();
  oiter.GoToBegin();

  while (!oiter.IsAtEnd())
  {
    if (maxLx < oiter.Get() * scaleFactor && std::abs(maxLx - oiter.Get() * scaleFactor) > tol)
    {
      std::cout << "FAIL: For period: " << 1.0 / frequency << " maxLx: " << maxLx
                << " tolerance exceeded by: " << std::abs(maxLx - oiter.Get() * scaleFactor) << std::endl;
      return false;
    }
    ++oiter;
  }

  // check if the maximal is obtained with a little bit bigger Gaussian
  filter->SetSigma(sigma_max * 1.05);
  outputImage->Update();
  oiter.GoToBegin();

  while (!oiter.IsAtEnd())
  {
    if (maxLx < oiter.Get() * scaleFactor && std::abs(maxLx - oiter.Get() * scaleFactor) > tol)
    {
      std::cout << "FAIL:  For period: " << 1.0 / frequency << " maxLx: " << maxLx
                << " tolerance exceeded by: " << std::abs(maxLx - oiter.Get() * scaleFactor) << std::endl;
      return false;
    }
    ++oiter;
  }


  std::cout << "f: " << frequencyPerImage << " max: " << maxLx << " expected max: " << expected_max << std::endl;

  if (std::abs(maxLx - expected_max) > .01)
  {
    std::cout << "FAIL: tolerance of expected max exceeded!" << std::endl;
  }

  return true;
}

} // namespace

int
itkRecursiveGaussianScaleSpaceTest1(int, char *[])
{
  bool pass = true;

  std::cout << " Testing First Order Gaussian" << std::endl;
  pass &= NormalizeSineWave(1.5, 1);
  pass &= NormalizeSineWave(2.5, 1);
  pass &= NormalizeSineWave(5, 1);
  pass &= NormalizeSineWave(10, 1);
  pass &= NormalizeSineWave(25, 1);

  std::cout << " Testing Second Order Gaussian" << std::endl;
  pass &= NormalizeSineWave(1.5, 2);
  pass &= NormalizeSineWave(2.5, 2);
  pass &= NormalizeSineWave(5, 2);
  pass &= NormalizeSineWave(10, 2);
  pass &= NormalizeSineWave(25, 2);

  std::cout << " Testing Spacing Invariance" << std::endl;
  pass &= NormalizeSineWave(5, 2, 0.01);
  pass &= NormalizeSineWave(5, 2, 100);

  if (!pass)
  {
    std::cout << "Test Failed!" << std::endl;
    return EXIT_FAILURE;
  }

  return EXIT_SUCCESS;
}
